Nitrogenase of Klebsiella pneumoniae nifV mutants.

The MoFe protein of nitrogenase from Klebsiella pneumoniae nifV mutants, NifV- Kp1 protein, in combination with the Fe protein from wild-type cells, catalysed CO-sensitive H2 evolution, in contrast with the CO-insensitive reaction catalysed by the wild-type enzyme. The decrease in H2 production was accompanied by a stoicheiometric decrease in dithionite (reductant) utilization, implying that CO was not reduced. However, CO did not affect the rate of phosphate release from ATP. Therefore the ATP/2e ratio increased, indicating futile cycling of electrons between the Fe protein and the MoFe protein. The inhibition of H2 evolution by CO was partial; it increased from 40% at pH6.3 to 82% at pH 8.6. Inhibition at pH7.4 (maximum 73%) was half-maximal at 3.1 Pa (0.031 matm) CO. The pH optimum of the mutant enzyme was lower in the presence of CO. Steady-state kinetic analysis of acetylene reduction indicated that CO was a linear, intersecting, non-competitive inhibitor of acetylene reduction with Kii = 2.5 Pa and Kis = 9.5 Pa. This may indicate that a single high-affinity CO-binding site in the NifV- Kp1 protein can cause both partial inhibition of H2 evolution and total elimination of acetylene reduction. Various models to explain the data are discussed.     

Nitrogenase of Klebsiella pneumoniae. Kinetics of the dissociation of oxidized iron protein from molybdenum-iron protein: identification of the rate-limiting step for substrate reduction.

Stopped-flow spectrophotometry and e.p.r. spectroscopy were used to study the kinetics of reduction by dithionite of the oxidized Fe protein of nitrogenase from Klebsiella pneumoniae (Kp2ox.) in the presence of MgADP at 23 degrees C at pH 7.4. The active reductant, SO2.-, produced by the predissociation of S2O4(2-) in equilibrium 2SO2.-, reacts with Kp2ox. (MgADP)2, with k4 = 3.0 X 10(6) +/- 0.4 X 10(6) M-1 X s-1. The inhibition of this reaction by the Mo-Fe protein (Kp1) has enabled the rate of dissociation of Kp2ox. (MgADP)2 from Kp1+ (the Kp2-binding site on Kp1) to be measured (k-3 = 6.4 +/- 0.8 s-1). Comparison with the steady-state rate of substrate reduction shows that the dissociation (k-3) of the complex Kp2ox. (MgADP)2-Kp1+, which is formed after MgATP-induced electron transfer from Kp2 to Kp1+, is the rate-limiting step in the catalytic cycle for substrate reduction.     

Nitrogenase of Klebsiella pneumoniae. Kinetic studies on the Fe protein involving reduction by sodium dithionite, the binding of MgADP and a conformation change that alters the reactivity of the 4Fe-4S centre.

The kinetics of reduction of indigocarmine-dye-oxidized Fe protein of nitrogenase from Klebsiella pneumoniae (Kp2ox) by sodium dithionite in the presence and absence of MgADP were studied by stopped-flow spectrophotometry at 23 degrees C and at pH 7.4. Highly co-operative binding of 2MgADP (composite K greater than 4 X 10(10) M-2) to Kp2ox induced a rapid conformation change which caused the redox-active 4Fe-4S centre to be reduced by SO2-.(formed by the predissociation of dithionite ion) with k = 3 X 10(6) M-1.s-1. This rate constant is at least 30 times lower than that for the reduction of free Kp2ox (k greater than 10(8) M-1.s-1). Two mechanisms have been considered and limits obtained for the rate constants for MgADP binding/dissociation and a protein conformation change. Both mechanisms give rate constants (e.g. MgADP binding 3 X 10(5) less than k less than 3 X 10(6) M-1.s-1 and protein conformation change 6 X 10(2) less than k less than 6 X 10(3) s-1) that are similar to those reported for creatine kinase (EC 2.7.3.2). The kinetics also show that in the catalytic cycle of nitrogenase with sodium dithionite as reductant replacement of 2MgADP by 2MgATP occurs on reduced and not oxidized Kp2. Although the Kp2ox was reduced stoichiometrically by SO2-. and bound two equivalents of MgADP with complete conversion into the less-reactive conformation, it was only 45% active with respect to its ability to effect MgATP-dependent electron transfer to the MoFe protein.     

Nitrogenase of Klebsiella pneumoniae. Distinction between proton-reducing and acetylene-reducing forms of the enzyme: effect of temperature and component protein ratio on substrate-reduction kinetics.

Non-linear rates of acetylene reduction and concomitant H2 evolution were observed for the nitrogenase of Klebsiella pneumoniae at 10 degrees C. A lag phase of 1-4 min, dependent on the ratio of Mo-Fe protein to Fe protein present, occurred before linear rates of acetylene reduction were achieved. A complementary burst phase for concomitant H2 evolution in the presence of acetylene was also observed. When the proton was the only reducible substrate present, linear rates of H2 evolution were observed. N2 was a poor substrate under these conditions. Similar lag and burst phases occurred at 30 degrees C, but only when a large molar excess of Mo-Fe protein with respect to Fe protein was present. The results at 10 degrees C show that the binding of acetylene to the enzyme stimulates electron flow, but that these electrons, which initially reduce protons, can only reduce acetylene after a lag phase that cannot be accommodated in the turnover time calculated under steady-state conditions.     

Purification, characterization and redox properties of hydrogenase from Methanosarcina barkeri (DSM 800)

A soluble hydrogenase from the methanogenic bacterium, Methanosarcina barkeri (DSM 800) has been purified to apparent electrophoretic homogeneity, with an overall 550-fold purification, a 45% yield and a final specific activity of 270 mumol H2 evolved min-1 (mg protein)-1. The hydrogenase has a high molecular mass of approximately equal to 800 kDa and subunits with molecular masses of approximately equal to 60 kDa. The enzyme is stable to heating at 65 degrees C and to exposure to air at 4 degrees C in the oxidized state for periods up to a week. The overall stability of this enzyme is compared with other hydrogenase isolated from strict anaerobic sulfate-reducing bacteria. Ms. barkeri hydrogenase shows an absorption spectrum typical of a non-heme iron protein with maxima at 275 nm, 380 nm and 405 nm. A flavin component, identified as FMN or riboflavin was extracted under acidic conditions and quantified to approximately one flavin molecule per subunit. In addition to this component, 8-10 iron atoms and 0.6-0.8 nickel atom were also detected per subunit. The electron paramagnetic resonance (EPR) spectrum of the native enzyme shows a rhombic signal with g values at 2.24, 2.20 and approximately equal to 2.0. probably due to nickel which is optimally measured at 40 K but still detectable at 77 K. In the reduced state, using dithionite or molecular hydrogen as reductants, at least two types of g = 1.94 EPR signals, due to iron-sulfur centers, could be detected and differentiated on the basis of power and temperature dependence. Center I has g values at 2.04, 1.90 and 1.86, while center II has g values at 2.08, 1.93 and 1.85. When the hydrogenase is reduced by hydrogen or dithionite the rhombic EPR species disappears and is replaced by other EPR-active species with g values at 2.33, 2.23, 2.12, 2.09, 2.04 and 2.00. These complex signals may represent different nickel species and are only observable at temperatures higher than 20 K. In the native preparation, at high temperatures (T greater than 35 K) or in partially reduced samples, a free radical due to the flavin moiety is observed. The EPR spectrum of reduced hydrogenase in 80% Me2SO presents an axial type of spectrum only detectable below 30 K.     

Stoichiometry, ATP/2e values, and energy requirements for reactions catalyzed by nitrogenase from Azotobacter vinelandii.

The stoichiometry of the nitrogenase ATP-dependent H2 evolution and ecetylene reduction reactions using S2O4(2-) as an electron source was studied by various techniques. For each mole of S2O4(2-) oxidized to 2SO3(2-) by the enzyme-catalyzed reactions at 25 degrees and pH 8, 1 mol of H2 (1 mol of ethylene for acetylene reduction) and two protons are produced. Under these conditions, 4.5 mol of ATP was hydrolyzed to ADP and inorganic phosphate for each S2O4(2-) oxidized. ATP/S2O4(2-) (ATP/2e) values determined at 5 degree intervals from 10 to 35 degrees were found to go through a minimum at 20 degrees. This effect is explained in terms of possible enzyme structure modifications. Calorimetric measurements for the enzyme-catalyzed H2 evolution and acetylene reduction reactions gave deltaH values of -32.4 and -75.1 kcal/mol of S2O4(2-), respectively.     

Nitrogenases from Klebsiella pneumoniae and Clostridium pasteurianum. Kinetic investigations of cross-reactions as a probe of the enzyme mechanism.

In combination with the Mo-Fe protein of nitrogenase from Klebsiella pneumoniae, the Fe protein of nitrogenase from Clostridium pasteurianum forms an active enzyme with novel properties different from those of either of the homologous nitrogenases. The steady-state rates of reduction of acetylene and H+ are 12% of those of the homologous system from C.pasteurianim. Acetylene reductase activity exhibited an approx. 10min lag at 30 degrees C before the rate of reduction became linear, consistent with a once-only activation step being necessary for acetylene reduction to occur. No such lag was observed for H2 evolution. The activity with N2 as a reducible substrate was very low, implying that acetylene reductase activity is not necessarily an accurate indication of nitrogen-fixing ability. This is of particular relevance to studies on mutant and agronomically important organisms. Stopped-flow spectrophotometric studies showed unimolecular electron transfer from the Fe protein to the Mo-Fe protein to occur at the same rate (k2 = 2.5 X 10(2)s-1) and with the same dependence on ATP concentration (apparent KD = 400 muM) as with the homologous Klebsiella nitrogenase. However, an ATP/2e ratio of 50 was obtained for H2 evolution, indicating that ATP hydrolysis had been uncoupled from electron transfer to substrate. These data indicate that ATP has at least two roles in the mechanism of nitrogenase action. The combination of the Mo-Fe protein of nitrogenase of C.pasteurianim and the Fe protein of K.pneumoniae were inactive in all the above reactions, except for a weak adenosine triphosphatase activity, 0.5% of that of the homologous K.pneumoniae system.     

Klebsiella pneumoniae nitrogenase. Inhibition of hydrogen evolution by ethylene and the reduction of ethylene to ethane.

Ethylene (C2H4) inhibited H2 evolution by the Mo-containing nitrogenase of Klebsiella pneumoniae. The extent of inhibition depended on the electron flux determined by the ratio of Fe protein (Kp2) to MoFe protein (Kp1) with KiC2H4 = 409 kPa ([Kp2]/[Kp1] = 22:1) and KC2H4i = 88 kPa ([Kp1]/[Kp2] = 21:1) at 23 degrees C at pH 7.4. At [Kp2]/[Kp1] = 1:1, inhibition was minimal with C2H4 (101 kPa). Extrapolation of data obtained when C2H4 was varied from 60 to 290 kPa indicates that at infinite pressure of C2H4 total inhibition of H2 evolution should occur. C2H4 inhibited concomitant S2O4(2-) oxidation to the same extent that it inhibited H2 evolution. Although other inhibitors of total electron flux such as CN- and CH3NC uncouple MgATP hydrolysis from electron transfer, C2H4 did not affect the ATP/2e ratio. Inhibition of H2 evolution by C2H4 was not relieved by CO. C2H4 was reduced to C2H6 at [Kp2]/[Kp1] ratios greater than or equal to 5:1 in a reaction that accounted for no more than 1% of the total electron flux. These data are discussed in terms of the chemistry of alkyne and alkene reduction on transition-metal centres.     

Nitrogenase. VII. Effect of component ratio, ATP and H2 on the distribution of electrons to alternative substrates.

Some kinetic properties of purified component I (Mo-Fe protein) and component II (Fe protein) of nitrogenase (EC 1.7.99.2) from Azotobacter vinelandii have been examined. The apparent Km values for reducible substrates (0.1 atm for N2, 0.01 atm for acetylene) and dithionite (0.5 mM) are similar for osmotically shocked cell lysates and purified components. However, the ATP dependence of acetylene and N2 reduction varies sigmoidally with ATP concentration and as a function of the relative and absolute concentration of components I and II in the assay. Acetylene is reduced in preference to N2 in competitive assays when component I is in relative excess. Acetylene reduction is not as dependent upon ATP concentration as is N2 reduction, so that acetylene is also a preferred substrate at lower ATP levels. Hydrogen specifically inhibits N2 reduction, diverting electrons to acetylene when both substrates are present in the assay. We propose a model of the enzyme activity, in which the substrates for reduction are bound to component I with electrons being activated by component II. ATP may be involved in activating electrons and in maintaining the appropriate conformation or reduction state of components to allow effective reduction of substrates. The relative rate of reduction of alternative substrates is dependent on the concentration of the particular state(s) capable of reacting with each substrate. The concentration of a particular state of component I is a function of components I, II and ATPL     

Isolation and nitrogenase activity of vesicles from Frankia sp. strain EAN1pec.

Vesicles, specialized cell structures thought to be the site of nitrogen fixation in the actinorhizal bacteria, were isolated from Frankia sp. strain EAN1pec by using French pressure disruption of mycelia followed by differential and isopycnic gradient centrifugation. The isolated vesicles reduced acetylene when incubated anaerobically with Mg2+ ions, ATP, and dithionite. No nitrogenase activity was detected in the disrupted mycelial fractions. Vesicles permeabilized by freeze-thaw or detergents showed increased rates of acetylene reduction due to increased permeability of dithionite. The effect on nitrogenase activity of different ATP concentrations was the same in normal and permeabilized vesicles. The endogenous respiratory rate of vesicles was significantly lower than that of mycelia, and the respiration rate of vesicles did not increase following the addition of succinate. The low respiratory activity of vesicles and their apparent dependence on externally supplied ATP for acetylene reduction suggest that the energy and reducing power for nitrogen fixation may be supplied from the mycelia to which they are attached.     

Substitution of histidine for arginine-101 of dinitrogenase reductase disrupts electron transfer to dinitrogenase

Dinitrogenase reductase from Klebsiella pneumoniae strain UN1041 has a histidine residue substituted for arginine at position 101. The mutant dinitrogenase reductase was purified and characterized in order to determine the importance of arginine-101 in the interaction between dinitrogenase and dinitrogenase reductase during electron transfer. Purified dinitrogenase reductase from UN1041 is a dimer of 67 kDa, contains a functional 4Fe-4S cluster, undergoes a MgATP-dependent conformational change, and is competent for ATP hydrolysis uncoupled from substrate reduction in the presence of dinitrogenase. However, the mutant protein is unable to support the reduction of protons or acetylene by dinitrogenase. A 100-fold molar excess of Kp2 from UN1041 does not inhibit electron transfer from wild-type dinitrogenase reductase to dinitrogenase. It is concluded that the interaction of dinitrogenase reductase with dinitrogenase during reductant-independent ATP hydrolysis is different than the interaction between the two proteins during electron transfer; the substitution of histidine for arginine at position 101 disrupts only the latter interaction. The same conclusions are reached using wild-type dinitrogenase reductase which has been ADP-ribosylated at arginine-101.     

Isolation of a new vanadium-containing nitrogenase from Azotobacter vinelandii

A new nitrogenase from Azotobacter vinelandii has been isolated and characterized. It consists of two proteins, one of which is almost identical with the Fe protein (component 2) of the conventional enzyme. The second protein (Av1'), however, has now been isolated and shown to differ completely from conventional component 1, i.e., the MoFe protein. This new protein consists of two polypeptides with a total molecular weight of around 200,000. In place of Mo and Fe it contains V and Fe with a V:Fe ratio of 1:13 +/- 3. The ESR spectrum of Av1' also differs from conventional component 1 in that lacks the g = 3.6 resonance that arises from the FeMo cofactor but contains an axial signal with gav less than 2 as well as inflections in the g = 4-6 region possibly arising from an S = 3/2 state. This new enzyme can reduce dinitrogen, protons, and acetylene but is only able to utilize 10-15% of its electrons for the reduction of acetylene.     

Long-range interactions between the Fe protein binding sites of the MoFe protein of nitrogenase

We report the properties and reactivity of the catalytically active heterologous nitrogenase formed between the Fe protein from Clostridium pasteurianum (Cp2) and the MoFe protein from Klebsiella pneumoniae (Kp1). Under turnover conditions, in the presence of MgATP, a stable 2:1 (Cp2)2Kp1 electron transfer complex is formed, in which the [4Fe-4S]+ centre of Cp2 is protected from chelation by alpha,alpha'-bipyridyl. However, the two Fe protein-binding sites on Kp1 are not equivalent, since a 1:1 Cp2.Kp1 complex was isolated by gel filtration. The non-equivalence of the Fe protein binding sites was also indicated by the inhibition pattern of Klebsiella nitrogenase by Cp2. The EPR spectrum of the isolated 1:1 Cp2.Kp1 complex showed an S=1/2 signal characteristic of dithionite-reduced Cp2 and signals with g values of 4.27, 3.73, 2.01 and 4.32, 3.63, 2.00 characteristic of the high- and low-pH forms of the FeMoco centre of Kp1, respectively. The unoccupied binding site of Kp1 of the isolated 1:1 Cp2Kp1 complex was shown to be catalytically fully functional in combination with Kp2. In contrast to homologous nitrogenases, which require MgATP for detectable rates of electron transfer from the Fe protein, stopped-flow kinetic studies revealed that electron transfer from Cp2 to Kp1 occurred in the absence of MgATP with a rate constant of 0.065 s(-1). Subsequently, a slower transient decrease and restoration of absorption in the electronic spectrum in the 500-700 nm region was observed. These changes corresponded with those in the intensity of the S=3/2 EPR signal of the FeMoco centres of Kp1 and were consistent with the transient reduction of the FeMoco centre of Kp1 to an EPR-silent form, followed by restoration of the signal at longer reaction times. These changes were not associated with catalysis since no evolution of H2 was detectable.     

Acetylene reduction with physiological electron donors by extracts and particulate fractions from nitrogen-fixing Azotobacter chroococcum

1. 1. Preparations were obtained from Azotobacter chroococcum which reduced acetylene to ethylene using physiological electron donors instead of sodium dithionite. These preparations fell into two categories: those which required catalytic amounts of benzyl viologen for acetylene reduction and those that did not.

2. 2. Acetylene reduction without benzyl viologen or sodium dithionite was observed only with particles that sedimented at 40 000 × g after disrupting bacteria in the French press or with preparations obtained by disrupting bacteria protected by a mixture of defatted bovine serum albumin-Ficoll-MgCl₂ with liquid N₂; supernatant fractions required benzyl viologen for acetylene reduction.

3. 3. Added ATP inhibited acetylene reduction by large particles; ATP and MgCl₂ were necessary for maximum acetylene reduction with bovine serum albumin-protected preparations.

4. 4. NADH and carbon substrates acted as electron donors but H₂ did not; NAD⁺ was necessary for maximum acetylene reduction with carbon substrates.

5. 5. Anaerobic conditions were necessary for maximum acetylene reduction in all cases.

Modes of reduction of nitrogen in heterocysts isolated from Anabaena species.

N2 fixation (acetylene reduction) has been studied with heterocysts isolated from Anabaena cylindrica and Anabaena 7120. In the presence of ATP and at very low concentrations of sodium dithionite, reducing equivalents for activity of nitrogenase in these cells can be derived from several compounds. In the dark, D-glucose 6-phosphate, 6-phosphogluconate and DL-isocitrate support acetylene reduction via NADPH. In the light, reductant can be generated by Photosystem I.     

Novel EPR signals associated with FeMoco centres of MoFe protein in MgADP-inhibited turnover of nitrogenase

Two novel electron paramagnetic resonance (EPR) signals arising from the [1Mo-7Fe-9S-homocitrate] (FeMoco) centres of MoFe protein of Klebsiella pneumoniae nitrogenase (Kp1) were observed following turnover under MgATP-limited conditions. The combination of the nitrogenase Fe protein of Clostridium pasteurianum showed similar signals. The accumulation of MgADP under these conditions causes the normal EPR signal of dithionite-reduced Kp1 (with g=4.3, 3.6, 2.01) to be slowly converted to novel signals with g=4.74, 3.32, 2.00 and g=4.58, 3.50, 1.99. These signals do not form in incubation of protein mixtures containing only MgADP, thus they may be associated with trapped intermediates of the catalytic cycle.     

Redox effects on the bacteriochlorophyll α-containing Fenna-Matthews-Olson protein fromChlorobium tepidum

The BChla-containing Fenna-Matthews-Olson (FMO) protein from the green sulfur bacteriumChlorobium tepidum was purified and characterized. Fluorescence spectra indicate that efficient excited state quenching occurs at neutral or oxidizing redox potentials. The major fluorescence lifetime at room temperature is approximately 60 ps in samples that are in neutral or oxidizing conditions, and approximately 2 ns in samples where the strong reductant sodium dithionite has been added. A similar change is observed in pump-probe picosecond absorbance difference experiments, where the long life time component increases after dithionite addition. A 16 Gauss wide EPR signal with g factor =2.005 is observed in samples without dithionite. This signal largely disappears upon addition of dithionite. Dithionite induces large reversibile changes in the 77 K absorbance spectra of the purified FMO protein and in whole cells. These results indicate that the FMO protein contains redox active groups, which may be involved in the regulation of energy transfer. Room temperature circular dichroism and low temperature absorption spectra show that dithionite also induces conformational or structural changes of the FMO protein complex.     

Purification and characterization of component A of the methane monooxygenase from Methylococcus capsulatus (Bath)

Methylococcus capsulatus (Bath) possesses a multi-component methane monooxygenase which catalyzes in vivo the conversion of methane to methanol. Component A of this enzyme system, believed to be the oxygenase component, has been purified to near homogeneity (95%). The native protein has a molecular weight of approximately 210,000 and is comprised of three subunits of Mr = 54,000, 42,000, and 17,000, which appear to be present in stoichiometric amounts suggesting an alpha 2, beta 2, gamma 2 arrangement in the native protein. Purified preparations of the protein are virtually colorless and examination of the uv/visible absorption spectrum revealed a peak around 280-290 nm and thereafter a steady decrease in absorbance to longer wavelengths. The ESR spectrum of the oxidized protein gave a signal at g = 4.3, presumably due to rhombic iron, and a radical signal at g = 2.01. Upon reduction with dithionite, a signal at g = 1.934 appeared. Chemical analyses of our purified preparations revealed the presence of iron (2.3 mol/mol) and zinc (0.2-0.5 mol/mol): molybdenum, copper, nickel, heme, and acid-labile sulfur were all virtually absent. On ultra thin layer isoelectric focusing, purified component A was judged to have a pI between 5.0 and 5.1. Extracts prepared from a variety of other methanotrophs failed to show any cross-reaction to antibody raised against M. capsulatus component A.     

EPR evidence of two structurally different diferric sites in Mycobacterium tuberculosis R2-2 ribonucleotide reductase protein

Mixed-valent species were generated in the diiron site of active (with tyrosyl free radical) and met (without radical) forms of protein R2-2 in a class Ib ribonucleotide reductase from Mycobacterium tuberculosis by low temperature reduction (γ-irradiation) at 77 K. The primary mixed-valent EPR signal is a mixture of two components with axial symmetry and g_av<2.0, observable at temperatures up to 77 K, and assigned to antiferromagnetically coupled high spin ferric/ferrous sites. The two components in the primary EPR signal can be explained by the existence of two structurally distinct μ-oxo-bridged diferric centers, possibly related to structural heterogeneity around the iron site, and/or different properties of the two polypeptide chains in the homodimeric protein after the radical reconstitution reaction. Annealing of the irradiated R2-2 samples to 143 K transforms the primary EPR signal into a rhombic spectrum characterized by g_av<1.8 and observable only below 25 K. This spectrum is assigned to a partially relaxed form with a μ-hydroxo-bridge. Further annealing at 228 K produces a new complex rhombic EPR spectrum composed of at least two components. An identical EPR spectrum was observed and found to be stable upon chemical reduction of Mycobacterium tuberculosis RNR R2-2 at 293 K by dithionite.     

Klebsiella pneumoniae nitrogenase: formation and stability of putative beryllium fluoride-ADP transition state complexes.

Incubation of the MoFe protein (Kp1) and Fe protein (Kp2), the component proteins of Klebsiella pneumoniae nitrogenase, with BeF(3)(-) and MgADP resulted in a progressive inhibition of nitrogenase activity. We have shown that at high Kp2 to Kp1 molar ratios this inhibition is due to the formation of an inactive complex with a stoichiometry corresponding to Kp1.{Kp2.(MgADP.BeFx)2}2. At lower Kp2:Kp1 ratios, an equilibrium between this 2:1 complex, the partially active 1:1 Kp1.Kp2.(MgADP. BeFx)2 complex, and active nitrogenase components was demonstrated. The inhibition was reversible since incubation of the 1:1 complex in the absence of MgADP and beryllium resulted in complete restoration of activity over 30 h. Under pseudo-first-order conditions with regard to nitrogenase components and MgADP, the kinetics of the rate of inhibition with increasing concentrations of BeF(3)(-) showed a square dependence on [BeF(3)(-)], consistent with the binding of two Be atoms by Kp2 in the complex. Analytical fplc gel filtration profiles of Kp1.Kp2 incubation mixtures at equilibrium resolved the 2:1 complex and the 1:1 complex from free Kp1. Deconvolution of the equilibrium profiles gave concentrations of the components allowing constants for their formation of 2.1 x 10(6) and 5.6 x 10(5) M(-1) to be calculated for the 1:1 and 2:1 complexes, respectively. When the active site concentration of the different species was taken into account, values for the two constants were the same, indicating the two binding sites for Kp2 are the same for Kp1 with one or both sites unoccupied. The value for K(1) we obtain from this study is comparable with the value derived from pre-steady-state studies of nitrogenase. Analysis of the elution profile obtained on gel filtration of a 1:1 ratio incubation mixture containing 20 microM nitrogenase components showed 97% of the Kp2 present initially to be complexed. These data provide the first unequivocal demonstration that Fe protein preparations which may contain up to 50% of a species of Fe protein defective in electron transfer is nevertheless fully competent in complex formation with MoFe protein.